Pilot design for OFDM systems with four transmit antennas

ABSTRACT

Pilot, preamble and midamble patterns are provided that are particularly suited for four transmit antenna OFDM systems. Pilots are inserted in a scattered manner for each of the four antennas, either uncoded, space-time coded in pairs, space-time frequency coded in pairs, or space-time-frequency coded.

FIELD OF THE INVENTION

The invention relates to pilot designs for OFDM (orthogonal frequencydivision multiplexing) systems with four transmit antennas.

BACKGROUND OF THE INVENTION

New applications of mobile communications demand high-speed andhigh-quality, bandwidth-efficient wireless access solutions. Theapplication of MIMO (multiple antennas both in the transmitter and inthe receiver) has been demonstrated to drastically improve channelcapacity compared to single-antenna systems. On the other hand, OFDM hasdemonstrated its high spectral efficiency and ability to deal withfrequency selective fading and narrow band interference. Therefore thecombination of OFDM with spectrally efficient multiple antennatechniques opens the door to high data-rate wireless communication.

Compared with the single input single output (SISO) systems, two kindsof gains are provided by the MIMO wireless systems, namely diversitygain and multiplexing gain. With diversity gain more reliable receptioncan be realized. With multiplexing gain the capacity of MIMO systemsincreases linearly with the number of transmit and receive antennas.This is due to the fact that a rich scattering environment can providemultiple data pipes within the same frequency band by using techniquessuch as space-time coding and space-time layering. Since the capacitycan be potentially increased by the application of multiple antennas,the use of up to four antennas at the transmitter and/or receiver hasbeen considered to achieve an increased data rate for a given linkperformance criterion, or to improve link performance for a given datarate.

For wireless propagation environments, the inherent temporal and spatialvariations of wireless channels impose more challenges on the design ofa reliable communication system. For noise and interference limitedsystems, coherent demodulation can achieve 2.5-3 dB SNR gain compared tothe differential demodulation. When coherent detection is performed in areceiver, reliable channel estimation is very important to the systemperformance. Channel estimation in MIMO systems is more complicatedbecause multiple channels should be obtained individually. As the numberof transmit antennas increases, the sensitivity to any channelestimation error becomes more pronounced.

OFDM modulation has been adopted by several standards, such as DVT-T,IEEE802.11a/g and IEEE802.16a/d. Different training schemes have beenemployed in these standards, including preamble, fixed-location pilotand variable-location pilot. However MIMO is not mandatory and is onlyadopted by IEEE802.16a as optional, and only two transmit antennas onthe base station side and one receive antennas on the SS (subscriberstation) side are employed. Since IEEE802.16a is designed for fixed andportable applications, the channel varies slowly. For the Wireless MAN(metropolitan area network) OFDM air-interface, the channel estimationis obtained from the preambles. For the Wireless MAN OFDMAair-interface, although variable location pilot symbols are introduced,they are only used to update the channel slowly.

SUMMARY OF THE INVENTION

According to one broad aspect, the invention provides a method oftransmitting over four transmit antennas

comprising: for each antenna, generating a respective sequence of OFDMsymbols, each OFDM symbol having a plurality of sub-carriers carrying atdata or pilots, and transmitting the sequence of OFDM symbols; whereinpilots are inserted for the four antennas collectively in blocks of twosub-carriers by two OFDM symbols scattered in time and frequency.

In some embodiments, pilots are inserted for the four antennascollectively in blocks of two sub-carriers by two OFDM symbols scatteredin time and frequency by: inserting such blocks of two sub-carriers bytwo OFDM symbols scattered in a first regularly spaced pattern in evenpairs of OFDM symbols; inserting such blocks of two sub-carriers by twoOFDM symbols scattered in a second regularly spaced pattern offset fromsaid first regularly spaced pattern in odd pairs of OFDM symbols.

In some embodiments, the first regularly spaced pattern comprises arepeating pattern of two pilot sub-carriers, ten data sub-carriers andthe second regularly spaced pattern comprises six data sub-carriersfollowed by a repeating pattern of two pilot sub-carriers and ten datasub-carriers.

In some embodiments, each block of two sub-carriers by two OFDM symbolscomprises a single pilot for each of the four antennas in a respectiveposition within the block.

In some embodiments, the single pilot for each of the four antennastakes the same position in every block of two sub-carriers by two OFDMsymbols.

In some embodiments, each block of two sub-carriers by two OFDM symbolsis divided into pilot pairs, each pilot pair being transmitted by arespective pair of antennas.

In some embodiments, each pilot pairs is arranged sequentially in time.

In some embodiments, each pilot pair is arranged sequentially infrequency.

In some embodiments, pilots are inserted for the four antennascollectively in blocks of two sub-carriers by two OFDM symbols scatteredin time and frequency in a repeating pattern of six OFDM symbolscomprising each comprising a first, second and third pair of OFDMsymbols, the method comprising: inserting such blocks of twosub-carriers by two OFDM symbols scattered in a first regularly spacedpattern in each first pair of OFDM symbols; inserting such blocks of twosub-carriers by two OFDM symbols scattered in a second regularly spacedpattern offset from said first regularly spaced pattern in each secondpair of OFDM symbols; and inserting such blocks of two sub-carriers bytwo OFDM symbols scattered in a third regularly spaced pattern offsetfrom said second regularly spaced pattern in each third pair of OFDMsymbols.

In some embodiments, pilots are inserted for the four antennascollectively in blocks of two sub-carriers by two OFDM symbols scatteredin time and frequency in a repeating pattern of OFDM symbols that is amultiple of two OFDM symbols in length.

According to another broad aspect, the invention provides a method oftransmitting over four transmit antennas comprising: for antenna,generating a respective sequence of OFDM symbols, each OFDM symbolhaving a plurality of sub-carriers carrying at data or pilots, andtransmitting the sequence of OFDM symbols; wherein for a first pair ofthe four antennas, pairs of pilots are inserted scattered in time andfrequency; wherein for a second pair of the four antennas, pairs ofpilots are inserted scattered in time and frequency in locationsdifferent from pilots for the first pair of antennas.

In some embodiments, for each pair of two pilots, the two pilots are notconsecutive in time or frequency.

In some embodiments, for each pair of two pilots, the two pilots arearranged consecutively in time.

In some embodiments, pilots are inserted in a repeating pattern of sixOFDM symbols comprising each comprising a first, second and third pairof OFDM symbols, wherein each pair of pilots is arranged sequentially intime: inserting pilot pairs for the first pair of antennas scattered ina first regularly spaced pattern in each first pair of OFDM symbols;inserting pilot pairs for the first pair of antennas scattered in asecond regularly spaced pattern offset from said first regularly spacedpattern in each second pair of OFDM symbols; inserting pilot pairs forthe first pair of antennas scattered in a third regularly spaced patternoffset from said second regularly spaced pattern in each third pair ofOFDM symbols; inserting pilot pairs for the second pair of antennasscattered in a fourth regularly spaced pattern in each first pair ofOFDM symbols offset from said first pattern; inserting pilot pairs forthe second pair of antennas scattered in a fifth regularly spacedpattern offset from said fourth regularly spaced pattern and said secondregularly spaced pattern in each second pair of OFDM symbols; insertingpilot pairs for the second pair of antennas scattered in a sixthregularly spaced pattern offset from said fifth regularly spaced patternand said third regularly spaced pattern in each third pair of OFDMsymbols.

According to another broad aspect, the invention provides a method oftransmitting over four transmit antennas comprising: for each antenna,generating a respective sequence of OFDM symbols, each OFDM symbolhaving a plurality of sub-carriers carrying at data or pilots, andtransmitting the sequence of OFDM symbols; wherein pilots are arrangedin groups of four consecutive pilots in time, each group of fourconsecutive pilots containing pilots for the four antennas.

In some embodiments, such groups of four consecutive pilots are insertedin each set of four consecutive OFDM symbols, and in each of a pluralityof spaced sub-carriers.

In some embodiments, each group of four consecutive pilots comprises apair of space time coded pilots for a first pair of antennas of the fourantennas, and a pair of space time coded pilots for a second pair ofantennas of the four antennas.

In some embodiments, each group of four consecutive pilots comprises asingle pilot for each of the four antennas.

In some embodiments, the location of the single pilot for each antennavaries across groups of four consecutive pilots.

In some embodiments, the method further comprises: using different pilotpatterns for respective four antenna transmitters to reduce interferencebetween pilots of different four antenna transmitters.

In some embodiments, the method further comprises: transmitting pilotswith a power higher than average power.

In some embodiments, data and pilots are transmitted using QPSK, withthe pilots being transmitted with a relative power boost.

In some embodiments, data is transmitted using a QAM constellation, andpilots are transmitted using QPSK with signal constellation points atcorners of the QAM constellation.

In some embodiments, the method further comprises transmitting at leastone fixed pilot for each of at least one of the four antennas.

In some embodiments, the method further comprises transmitting at leastone fixed pilot for each of two pairs of antennas within said fourantennas.

In some embodiments, the method further comprises transmitting at leastone fixed signalling channel for each of two pairs of antennas withinsaid four antennas.

In some embodiments, the method further comprises: transmittingrelatively reliable signalling channel information proximal in time andfrequency to locations of pilots.

In some embodiments, transmitting relatively reliable signalling channelinformation proximal in time and frequency to locations of pilotscomprises: for pairs of antennas of the four antennas, transmittingspace time coded signalling channel information pairs adjacent in timeto pairs of pilots.

In some embodiments, for a given antenna, a spacing between pilots inthe time direction is determined with consideration to the maximumDoppler frequency, while a spacing between pilot in the frequencydirection is determined with consideration to a delay spread ofmulti-path fading.

According to another broad aspect, the invention provides a method oftransmitting over four transmit antennas comprising: for each antenna,generating a respective sequence of OFDM symbols, each OFDM symbolhaving a plurality of sub-carriers carrying at data or pilots, andtransmitting the sequence of OFDM symbols; wherein the OFDM symbolsinclude at least one preamble OFDM symbol or midamble OFDM symbolcomprising a repeating pattern of four pilot sub-carriers for the fourantennas.

In some embodiments, the repeating pattern of four pilot sub-carrierscomprises a first space-frequency coded pilot pair for a first pair ofthe four antennas, and a second space-frequency coded pilot pair for asecond pair of the four antennas.

In some embodiments, the repeating pattern of four pilot sub-carrierscomprises a respective pilot for each of the four antennas withoutoverlapping.

In some embodiments, the preamble comprises two identical OFDM symbols.

In some embodiments, the method further comprises transmitting the pairof identical OFDM symbols by: transmitting a prefix; transmitting afirst OFDM symbol having first and second portions in time, the secondportion being identical to the prefix, such that the prefix functions asa cyclic prefix for the first OFDM symbol; transmitting a second OFDMsymbol identical to the first OFDM symbol, such that the second portionof the first OFDM symbol functions as a prefix for the second OFDMsymbol.

In some embodiments, the prefix and pair of identical symbols aretransmitted with a total time duration equal to a time for transmittinga prefix and a single OFDM symbol that is not part of the preamble ormidamble.

In some embodiments, antennas can be turned off and pilot groupsassigned to the turned off antennas re-assigned to the remaining twotransmit antennas to improve the channel estimation performance for fastfrequency selective fading channel.

In some embodiments, the four transmit antennas form part of a singlebase station transceiver.

In some embodiments, the four transmit antennas form part of multiplebase station transceivers.

In some embodiments, the four transmit antennas form part of multiplemobile stations.

In some embodiments, the pilots are space-time coded.

In some embodiments, the pilots are space-frequency coded.

In some embodiments, the pilots are space-time-frequency coded.

In some embodiments, the pilots are uncoded.

According to another broad aspect, the invention provides a method oftransmitting over at least two transmit antennas comprising: for eachantenna, generating a respective sequence of OFDM symbols, each OFDMsymbol having a plurality of sub-carriers carrying at data or pilots,and transmitting the sequence of OFDM symbols; wherein pilots areinserted for the antennas collectively in blocks of two sub-carriers bytwo OFDM symbols scattered in time and frequency.

According to another broad aspect, the invention provides a method oftransmitting a pair of identical OFDM symbols comprising: transmitting aprefix; transmitting a first OFDM symbol having first and secondportions in time, the second portion being identical to the prefix, suchthat the prefix functions as a cyclic prefix for the first OFDM symbol;transmitting a second OFDM symbol identical to the first OFDM symbol,such that the second portion of the first OFDM symbol functions as aprefix for the second OFDM symbol.

In another embodiment, a transmitter comprising four transmit antennasis provided, the transmitter is adapted to implement one of the methodssummarized above.

In another embodiment, at least two base station transceiverscollectively comprising four transmit antennas are provided, the atleast base station transceivers are adapted to implement one of themethods as summarized above.

In another embodiment, at least two mobile stations collectivelycomprising four transmit antennas are provided, the at least two mobilestations are adapted to implement one of the methods as summarizedabove.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred embodiments of the invention will now be described withreference to the attached drawings in which:

FIG. 1 is a block diagram of a four antenna OFDM transmitter in whichdata and pilot are modulated onto each OFDM signal;

FIG. 2 is a block diagram of a four antenna OFDM transmitter in whichdata, TPS and pilot are modulated onto each OFDM signal;

FIG. 3 is a block diagram of a four antenna OFDM system in which thefour antennas are located on respective mobile stations eachtransmitting data and pilot;

FIGS. 4A, 4B, 5A, 5B, 6, 7A, 7B, 8, 9A, 9B, 10A, 10B, 10C, 11-13, 14A,14B, 15, 16A, and 16B are time-frequency diagrams of scattered pilotpatterns for use with four antenna OFDM systems provided by embodimentsof the invention;

FIGS. 17A, 17B, and 17C are examples of how power boosts may be appliedto pilot symbols;

FIGS. 18 and 19 are time-frequency diagrams of pilot patterns that aresuitable for use as a preamble or midamble; and

FIG. 20 is a detailed example of how two OFDM symbols for use in apreamble or midamble can be transmitted during the nominal single OFDMsymbol duration.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Problems and disadvantages of the existing solutions which included in802.11a/g and 802.16a are that they doe not support MIMO transmissionwith four transmit antennas, do not support high speed mobility and arenot optimal for TDD employment.

A system block diagram is shown in FIG. 1. A MIMO transmitter 10 isshown having four transmit antennas 12,14,16,18. For each transmitantenna, there is a respective OFDM modulator 20,22,24,26. The OFDMmodulators 20,22,24,26 have respective data inputs 28,30,32,34 and pilotinputs 36,38,40,42. It is noted that while one OFDM modulator is shownper antenna, some efficiencies may be realized in combining thesefunctions. Alternatively, since the pilot channel inputs arepredetermined, this can be determined within the OFDM modulators per se.Furthermore, while separate data inputs 28,30,32,34 are shown, these maybe used to transmit data from one or more sources. Encoding may or maynot be performed. Details of the OFDM modulators are not shown. It iswell understood that with OFMD modulation, the data and the pilotchannel symbols are mapped to sub-carriers of an OFDM signal. In orderto generate a particular pilot design, this involves controlling thetiming of when data symbols versus pilot symbols are applied toparticular sub-carriers and for particular OFDM symbol durations.

In another system block diagram, shown in FIG. 2, the OFDM modulators20,22,24,26 also receive respective TPS (transmit parameter signalling)data 43,44,46,48 which is also used in generating the OFDM signals. Onceagain, the TPS symbols are mapped by the OFDM modulator to appropriatesub-carrier locations and OFDM symbol durations.

In yet another embodiment, shown in FIG. 3, four mobile stations60,62,64,66 are shown. Each of these has their own OFDM modulator andtransmit antenna. These embodiments can function similar to theembodiments of FIGS. 1 and 2 but with the respective signals beinggenerated in different mobile stations rather than in a single MIMOtransmitter. Collectively, the four mobile stations 60,62,64,66 functionas a MIMO transmitter.

Coherent detection is required to achieve high spectrum efficiency.Pilot assisted channel estimation is a widely applied approach tomeasure the change of the amplitude and phase of the transmitted signalscaused by the corruption of the radio channel.

For pilot-assisted channel estimation, known pilot symbols aremultiplexed into the data stream at certain sub-channels (sub-carriers)and certain times. The receiver interpolates the channel informationderived from the pilot symbols and obtains the channel estimates for thedata symbols.

Embodiments of the invention provide pilot channel designs for fourantenna OFDM.

Various pilot channel designs that might, for example, be employedwithin the systems of FIGS. 1, 2 and 3 will now be described.

In designing the new pilot designs, consideration is made to the factthat pilot symbols introduce the overhead. As such, from a channelutilization standpoint, fewer pilot symbols is better. For a channelwith both frequency and time dispersion, pilot symbols have to beinserted both in frequency and time direction. The spacing between pilotsymbols in time direction is determined with consideration to themaximum Doppler frequency, while the spacing between pilot symbols inthe frequency direction is determined with consideration to the delayspread of the multi-path fading. In some embodiments, for broadbandmobile access application, the channel is updated more frequently bothin the frequency direction and in the time direction in order to obtainthe correct channel responses across the whole bandwidth during thewhole transmission period. To deal with high frequency and timedispersions, a denser pilot grid is preferably employed.

Some embodiments feature a TDD (time division duplex) deployment. Tosupport slot-based TDD switching, in some embodiments, channelestimation processing is performed slot by slot, i.e. the channelresponses are calculated only based on the pilot symbols in the currentslot.

FIGS. 4 through 16B are examples of pilot designs provided by variousembodiments of the invention. In all of these drawings, time is shown onthe vertical axis and frequency is shown on the horizontal axis. Thesmall circles each represent the content of a particular sub-carriertransmitted at a particular time. A row of such circles represents thesub-carriers of a single OFDM symbol. A vertical column of any of thesedrawings represents the contents transmitted on a given OFDM sub-carrierover time. All of the examples show a finite number of sub-carriers inthe frequency direction. It is to be understood that the number ofsub-carriers in an OFDM symbol is a design parameter and that thedrawings are to be considered to give only one example of a particularsize of OFDM symbol.

Referring now to FIG. 4A, a first example pilot design is shown. Withthis design, there is a repeating pattern of four OFDM symbols with foursuch sets of four OFDM symbols indicated at 100,103,104,105. Therepeating pattern 100 consists of a first pair of OFDM symbols 101 and asecond pair of OFDM symbols 102. During OFDM symbols 101, and insub-carrier locations 112, pilot symbols for antennas 1, 2, 3 and 4(indicated at 110 in the legend) are inserted. Between each such blockof pilot symbols, there is a block of data sub-carriers 114 (data beingindicated at 108 in the legend). In the particular example illustrated,there are 10 data sub-carriers between the blocks of pilot carriers.However, it is to be understood that other numbers could alternativelybe employed.

The next set of OFDM symbols 102 is similar to the first set 101 but forthe fact that the pattern begins with the set of data sub-carriers andthen a set of pilot carriers. The pilot symbols in the second set ofsymbols 102 are offset from the pilot symbols in the first set 101, byfour sub-carriers in the illustrated example. Other offsets arepossible.

Each block of pilot symbols includes one pilot for each of the fourantennas. The particular location of the pilot symbol for a givenantenna in such blocks is not specified in the example of FIG. 4A.Rather, each block must include at least one pilot symbol from each ofthe four antennas. Various specific examples are given below.

With this design, a TDD transmission scheme is possible withtransmission taking place in blocks of multiples of two OFDM symbols.

At the receiver, channel estimation is performed for the pilotlocations. Then interpolation is performed in the time direction firstfollowed by interpolation in the frequency direction. The timeinterpolation is preferably done first because there is likely to bemore stability in the time direction. In the illustrated example, thepattern repeats every four OFDM symbols with the second two OFDM symbolshaving pilot locations offset from the pilot locations in the first pairof OFDM symbols. It can be seen that patterns of other multiples of twoOFDM symbols can alternatively be employed. For example, in a repeatingpattern containing six OFDM symbols, the pilot symbols would be offsetfrom each other in the second pair and again in the third pair beforerepeating the pattern again starting at the seventh OFDM symbol. Anexample of this is given below in FIG. 8.

Referring now to FIG. 4B, shown is another example pilot pattern that isvery similar to that of FIG. 4A. However, in this example in addition tothe four pilot symbol blocks that are inserted each of which consists ofa pilot for each of the four antennas, these being inserted in a socalled “variable manner” since the pilot symbols for a given antenna arenot always on, there are also shown fixed pilot symbols at 122 for afirst pair of antennas 1 and 2, and fixed pilot symbols 124 for antennas3 and 4. In the particular example shown, the repeating pattern consistsof a fixed pilot pair for antennas 1 and 2, three data sub-carrierlocations, two sub-carrier locations containing variable pilot symbolsand data locations; three data sub-carriers; a fixed pilot pair forantennas 3 and 4 followed by 18 sub-carriers containing both data onlysub-carriers and variable pilot plus data sub-carriers, another fixedpilot pair for antennas 1 and 2, eight sub-carriers containing datasub-carriers and data plus variable pilot sub-carriers, and anotherfixed pilot for antennas 3 and 4. It is to be understood that this is avery particular example. The fixed pilots can be inserted anywhere. Insome embodiments, they can overlap the variable pilots. Thus, theparticular pattern in which there are three data sub-carriers separatingthe fixed pilot symbols from the variable pilot symbols is to beconsidered only one possibility.

Turning now to FIG. 5A, this is a specific example of the pilot patternof FIG. 4A. Shown are two sets of four OFDM symbols 130,133 with thefirst set of four OFDM symbols 130 shown to include a first pair of OFDMsymbols 131 and a second pair of OFDM symbols 132. Data sub-carriers areindicated at 140; pilot pairs for antennas 1 and 3 are indicated at 142;pilot pairs for antennas 2 and 4 are indicated at 144. In thisembodiment, unlike FIG. 4A where the particulars of the pilot symbols ineach four pilot block were unspecified, each block of four pilot symbolsis shown to include a first pair 150 for antennas 1 and 3, and thesecond pair 152 for antenna pair 2 and 4. The pairs are arrangedvertically (i.e. in time).

FIG. 5B is very similar to FIG. 5A, but in this example the pilot pairsare arranged horizontally. In the particular example, shown are two setsof four OFDM symbols 160,163 with OFDM symbol group 160 shown to includetwo pairs of OFDM symbols 161,162. In these pairs, there is ahorizontally (i.e. in frequency) arranged pilot pair for antennas 1 and3 and a horizontally arranged pilot pair for antennas 2 and 4. In thisexample, data sub-carriers are indicated at 170, pilot pairs forantennas 1 and 3 are indicated at 172, and pilot pairs for antennas for2 and 4 are indicated at 174. Yet another possible combination isantennas 1&4, and 2&3.

Referring now to FIG. 6, shown is another pilot design provided byanother embodiment of the invention. This design features fixed pilotlocations 166 for antennas 1 and 2, and fixed pilot locations 168 forantenna pairs 3 and 4. This is similar to the fixed pilot design of FIG.4B. In this case, for the first eight OFDM symbols, the horizontal pilotpair arrangement of FIG. 5B is used while for the next eight OFDMsymbols, the pilot pair layout of FIG. 5A is employed. That is to say inthe first OFDM symbols, the pilot pairs for a given antenna pair arearranged horizontally (i.e. in frequency) and during the next eight OFDMsymbols, the pilot pair for a given antenna pair is arranged vertically(i.e. in time).

The pilot designs described with reference to FIGS. 5A, 5B and 6 have aspecified pilot pair locations for antenna pairs, but have not beenparticular as to the location of a given pilot for a given antenna. Inthe example of 7A, the pilot design is specified to this degree ofgranularity. In particular, with this example, again four repeatingpatterns of four OFDM symbols are shown at 180,183,184 with the firstset of four OFDM symbols 180 consisting of a first pair of OFDM symbols181 and a second pair of OFDM symbols 182. Blocks of pilot symbols areinserted in time and frequency in a manner the same as that shown inFIG. 4A. Here, each set of four pilot symbols is shown to include apilot symbol for antenna 1 192, a pilot symbol for antenna 2 194, apilot symbol for antenna 3 196, and a pilot symbol for antenna 4 196arranged in a particular manner. Data sub-carriers are indicated at 190.

Referring now to FIG. 7B, this pilot design is similar to that of FIG.7A in that each block of four pilot symbols has specified locations forthe pilot symbols for each of the four antennas. This design alsofeatures a fixed pilot 185 for antennas 1 and 2 and a fixed pilotsymbols 186 for antennas 3 and 4. There are also different antennacombination possibilities for fixed pilots as described previously forthe variable pilots.

Turning now to FIG. 8, shown is another pilot design in which the layouthas a repeating pattern every six OFDM symbols. Four sets of OFDMsymbols are shown at 200,204,206,208. The first set 200 is shown toinclude three pairs of OFDM symbols 201,202,203. In this example, thethree pairs of OFDM symbols 201,202,203 have blocks of four pilotsymbols inserted but in offset locations from each other. Thus, the fourpilot blocks in OFDM symbols 202 are offset from those of OFDM symbols201, and the four pilot blocks of OFDM symbols 203 are again offset fromthose of OFDM symbols 202. In this particular case, there is a repeatingpattern consisting of two sub-carriers during which variable pilotsymbols and data are transmitted, two sub-carriers during which onlydata followed by sub-carriers during which only data are transmitted.Data is indicated at 210; pilot symbols for antennas 1 and 3 areindicated at 212; pilot symbols for antennas 2 and 4 are indicated at214. It can be seen that the arrangement of the pilot symbols within thefour pilot symbols block has pilot pairs for a given pair of antennasarranged vertically, i.e. in time. It is to be understood that the samesix OFDM symbol pattern can be employed but with different layouts forthe pilots in the four pilot blocks. These pilot blocks can be made ofhorizontally arranged pairs, or have some other fixed or variabledesign. Furthermore, while the example shows two data sub-carriersbetween each pair of sub-carriers that contain the variable pilotsymbols, other separations can alternatively be employed.

Another pilot design is shown in FIG. 9A. This design also features asix OFDM symbol repeating pattern with four such groups of six OFDMsymbols indicated at 220,224,226,228. The six OFDM symbols 220 are shownto include three pairs of OFDM symbols 221,222,223. With this design,the pilot symbols for the four antennas are not arranged in squareblocks of four. Rather, as can be seen from the layout of data 230,pilot symbols for antennas 1 and 3 232 and pilot symbols for antennas 2and 4 234, the pilot symbols for antennas 1 and 3 are inserted at afirst sub-carrier location 225 for the first pair of OFDM symbols; at asecond sub-carrier location 227 for the second pair of OFDM symbols 222;and a third sub-carrier location 229 for the third pair of OFDM symbols223. These sub-carrier locations are offset from each other by threeOFDM sub-carrier locations. This pattern then repeats itself both in thehorizontal and vertical direction. Similarly, pilot pairs for the secondpair of antennas 2 and 4 are inserted at sub-carrier 231 for the firstpair of OFDM symbols, sub-carrier 233 for the second pair of OFDMsymbols and sub-carrier 235 for the third pair of OFDM symbols 223. Thispattern then also repeats in time and frequency. It can be seen that thepilot pairs for the pairs of antennas are arranged vertically (i.e. intime) but that the pilot pairs for the two pairs of antennas are notarranged adjacent to each other. Of course, other antenna combinationsare possible.

Another example is shown in FIG. 9B. A similar scattered pilot is shownfor the four antennas, but this example also includes fixed fastsignalling channel pilots (FSCH) 236 for antennas 1 and 3, and 237 forantennas 2 and 4. A fast signalling channel is analogous to atransmission parameter channel described earlier.

The particular location of the pilot pairs shown in FIGS. 9A and 9B areto be considered a particular example. Another example is shown in FIG.10A. This design is basically the same as that of FIG. 9A but with thelocation of the pilot pairs being slightly different. The location ofthe pilot pairs for antennas 1 and 3 is identical to that of FIG. 9A. Inthis case, the pairs for antennas 2 and 4 are offset from the pairs forantennas 1 and 3 by one sub-carrier location whereas they were offset byfour sub-carrier locations in the example of FIG. 9A. In the particularexample shown, there are two groups of six OFDM symbols 244,246 thatcontain repeating patterns of pilot symbols. The first set of six OFDMsymbols 244 contains pairs 240,241,242. Data sub-carriers are indicatedat 248; pilot symbols for antennas 1 and 3 are indicated at 250 andpilot symbols for antennas 2 and 4 are indicated at 252. Vertical pilotpair arrangements similar to those of in FIGS. 9A and 10A can also beapplied to the situation which features 4 OFDM symbol repeating pattern,and more generally a multiple of 2 OFDM symbols.

In some embodiments, a different pilot pattern is employed by differentbase stations. This allows the pilot pattern of a given base station tobe transmitted and received with higher reliability than would be thecase if all base stations were transmitting on the same exact pilotpatterns. The illustrated example shows eight different patterns thatcan be assigned to base stations. These patterns can be fixed or varyingover time for a given base station. Of course the particular patternshown are to be considered only particular examples. More generally, inthis embodiment, different pilot patterns are employed for differentbase stations.

FIG. 10C shows a particular example of how a PN sequence can be mappedto a four antenna pilot.

In one example, an offset pattern of the scattered pilot may be derivedfrom [ID_(cell)]modulo8, where ID_(cell) is a positive integer assignedby MAC to identify the BS sector. In one embodiment, there are 8orthogonal scattered pilot offset patterns. In addition, the scatteredpilot pattern allows the fast pilot extraction by using sub-FFT insteadof the full size FFT to reduce the portal device power consumption. TheFSCH can be demodulated and by using decision feedback the FSCH can beconverted into additional pilots to assist the channel estimation. Thescattered pilot pattern for 4 transmit antennas can be used for 2transmit antennas to increase the pilot density in the excessive delayspread environment, e.g. ITU VB channel.

The table below lists example orthogonal scattered pilot patterns.

Pattern-0 Pattern-1 Pattern-2 Pattern-3 Pattern-4 Pattern-5 Pattern-6Pattern-7 (i = 0) (i = 1) (i = 2) (i = 3) (i = 4) (i = 5) (i = 5) (i =5) OFDM Pair-1 0 1 2 3 4 5 6 7 {N^(i) _(OFFSET)(0)} OFDM Pair-2 5 6 7 89 10 11 12 {N^(i) _(OFFSET)(1)} OFDM Pair-3 11 12 13 14 15 16 1 2 {N^(i)_(OFFSET)(2)}

The scattered pilot pattern may be defined as:

SP_(k₁)^(i)(m) = N_(OFFSET_(k₁))^(i)(m) + 16P_(k)SP_(k₂)^(i)(m) = N_(OFFSET_(k₂))^(i)(m) + 16P_(k)N_(OFFSET_(k₁))^(i)(m) = (N_(OFFSET)⁰(m) + i)mod 16N_(OFFSET_(k 2))^(i)(m) = (N_(OFFSET)^(i)(m) + 8)mod 16where:

-   SY^(i) _(k) ₁ is the sub-carrier index of variable-location pilots    for antennas 1&3;-   SP^(i) _(k) ₂ is the sub-carrier index of variable-location pilots    for antennas 2&4;-   N^(i) _(OFFSET)(m) is the sub-carrier indices offsets for m^(th)    OFDM-pair and i^(th) rotation pattern;-   M=[0,1,2] is a modulo 3 function of the OFDM-pair;-   P_(k)=[0,1,2 . . . , N_(varLocPilot)−1], N_(varLocPilot) is the    number of variable location pilots for each antenna-pair; and-   I=[0,1,2, . . . 11] is the pilot pattern index.

An example cyclic shift scattered pilot pattern is shown in FIG. 10B asdiscussed above.

The scattered pilot may be concatenated or mapped by STTD (space-timetransmit diversity) code and cell/sector/beam specific PN sequence. Anexample mapping of the STTD code for the scattered pilot is shown inFIG. 10C as discussed above.

The STTD encoding of the scattered pilot allows assisting receiverspecific operations such as average channel estimation over two OFDMsymbols. The PN encoded scattered pilot allows inter-cell interferenceaveraging, fine timing synchronization and cell/sector/beamidentification, and channel quality indicator estimation, for instance.

Illustrative example scattered pilot parameters for 2048-OFDM with 20MHz bandwidth are listed in the table below.

Parameter Value Number of dc carriers  1 Number of guard carriers, left159 Number of guard carriers, right 160 N_(used), Number of usedcarriers 1728  Total number of carriers 2048  Number ofvariable-location pilot 288 (for 4 transmit antennas); 144 (for 2transmit antennas) Number of data carriers 1440 (for 4 transmitantennas) 1584 (for 2 transmit antennas) Number of FSCH carriers 108Number of variable-location pilots 108 (for 4 transmit which coincidewith FSCH antennas) 54 (for 2 transmit antennas) Number of FSCH patterns 8 The frequency offset indices of 32n + 4k & 32n + 4k + 1 FSCHsub-carriers n = 0, 1, . . . , 53; k = 0, 1, . . . , 8

Referring now to FIG. 11, shown is another example pilot design that inaddition to including pilot pairs for the various antennas, includes TPS(transmission parameter signals) locations. These can be used totransmit signalling information and/or information characterizing thetransmissions.

In the particular example illustrated, there is a repeating pattern of12 OFDM symbols. The first six OFDM symbols consist of pairs280,281,282. The first two sub-carriers 300 are used for TPS forantennas 1 and 3 and TPS for antennas 2 and 4 respectively. Similarly,the last two sub-carriers 302 are used for this same purpose. Betweenthe two pairs of sub-carriers used for TPS, there is an arrangement inwhich blocks of four pilot symbols are inserted similar to the layout ofFIG. 8 with two data sub-carriers separating each variable pilotsub-carrier location. The first pair of OFDM symbols 280 has pilotblocks 304,306; the second pair of OFDM symbols 281 has pilot blocks308,310,312; and third pair of OFDM symbols 282 has pilot blocks320,322,324. In this particular example, in addition to the pilot blockslaid out as described above, there are TPS blocks 314,316,318 insertedin the second OFDM symbol pair 281. Similar TPS blocks are inserted inOFDM symbol pair 286 but in a different frequency location. These TPSblocks are used to transmit additional TPS information. Preferably, theadditional TPS blocks are of sufficient reliability that they can bedecoded accurately. Assuming accurate decoding of these TPS blocks canbe achieved, then these sub-carrier locations can also be treated aspilot symbols for the purpose of channel estimation. It is most likelythat proper decoding of the TPS blocks will occur if the TPS blocks aresituated proximal to, and preferably adjacent to pilot blocks as shownin the illustrated example. More preferably, each TPS block is arrangedadjacent in time to a pilot block. This is because typically the channelwill change less in the time direction than in the frequency directionand this will further enhance the reliability of the decoding performedfor the TPS block.

A particular pilot and TPS block layout has been shown in FIG. 11. Moregenerally, in any of the embodiments described herein TPS blocks may beinserted in any location, preferably proximal to the location of pilotinsertions. At the receiver, both the pilot blocks and the TPS blockscan be used as input to the interpolation process that yields channelestimates for all sub-carriers and all OFDM symbols. In a particularexample shown, the vertical arrangement of pilot symbols for antennapairs is shown. This same arrangement is used for the TPS data. Thus, itis preferred that the TPS for a given antenna be inserted in the samesub-carrier location as a pilot for the same antenna.

Referring now to FIG. 12, in another example of a pilot pattern thatincludes TPS, the basic pilot layout is very similar to that shown inFIG. 10 with the pilot pairs for the two sets of antennas being offsetfrom each other by one sub-carrier location and then further offset fromeach other during adjacent pairs of OFDM symbols. In the illustratedexample, the repeating pattern is 10 OFDM symbols long with two suchpatterns indicated at 330,332. OFDM symbol 330 consists of five pairs ofOFDM symbols 333,334,335,336,337. Data sub-carriers are indicated at340; pilot pairs for antennas 1 and 3 at 342; pilot pairs for antennas 2and 4 at 344; TPS from antennas 1 and 3 at 346; TPS for antennas 2 and 4at 348. In this example, it can be seen that during OFDM symbols 334,336TPS signalling is inserted adjacent in time to the pilot pair insertionsduring OFDM symbols 335. This is seen at sub-carrier 341 which consistsof two OFDM symbol durations during which data is transmitted; two OFDMsymbol durations during which TPS from antennas 1 and 3 is transmitted;two OFDM symbol durations during which pilot data for antennas 1 and 3is transmitted; and two OFDM symbol durations during which TPS data forantennas 1 and 3 is transmitted followed by two more OFDM symboldurations during which data is transmitted. A similar pattern is shownat 343 for antennas 2 and 4. This is another example similar to that ofFIG. 11 in which TPS data is inserted adjacent in time to the insertionof pilot pairs. Once again, the TPS data, if reliably encoded andreliably decoded at the receiver can be used as further pilot locationsfor the purpose of channel estimation.

Examples have now been shown in which the pilot symbols are arranged insquare blocks of four, and in pairs of separated blocks of two pilotsymbols. The embodiment of FIG. 13 differs from these in that the pilotsymbols for the antennas are all separate from each other. The datasub-carriers are indicated at 380; pilot symbols for antenna 1 at 382;pilot symbols for antenna 3 at 384; pilot symbols for antenna 2 at 386;pilot symbols for antenna 4 at 388. Shown is a repeating pattern of sixOFDM symbols with four such patterns indicated at 370,372,374,376. Inthis repeating pattern, there is a scattered pilot for each of the fourantennas but in locations offset from each other. For example, duringthe first set of six OFDM symbols 370, pilot symbols 382 for the firstantenna are inserted in a scattered manner in OFDM symbols 372,374,376.Pilot symbols 386 for the second antenna are inserted during OFDMsymbols 371,373,375. Pilot symbols 384 for the third antenna areinserted during OFDM symbols 372,374,376. Finally, pilot symbols 388 forthe fourth antenna are inserted in OFDM symbols 371,373,375. In thisparticular example, the pilot symbols inserted for a given antenna areseparated in frequency by 11 sub-carriers. Every second OFDM symbolcontains pilot symbols for each antenna. Of course it is to beunderstood that different pilot densities than those particularly shownin FIG. 13 may alternatively be employed. Furthermore, while the exampleof FIG. 13 shows a repeating pattern of six OFDM symbols, the concept ofusing separately scattered pilot symbols for each antenna can be equallyapplied to patterns having different lengths.

Referring now to FIG. 14A, shown is another pilot design provided byanother embodiment of the invention. This pilot design repeats inpatterns of four OFDM symbols with three sets of four OFDM symbolsindicated at 400,402,404. During each set of four OFDM symbols, a set offour pilot symbols are inserted in a vertical manner for the fourantennas. Data symbols are indicated at 408 and pilot symbols at 410. Inthe pattern shown, in sub-carrier locations 406, the sets of four pilotsymbols are inserted with one pilot for each antenna, the location ofthe particular sub-carriers for particular antennas not being specified.Thus, sub-carrier locations 406 are transmitted during which no data istransmitted. Between sub-carriers 406 are blocks of data sub-carriers407 six in length. In the particular example, the vertical pilotinsertions is periodic being inserted every seventh sub-carrier. It isto be understood that other spacings can be employed. Furthermore, thespacings do not necessarily need to be uniform so long as the receiverknows where the pilot symbols are located.

Referring now to FIG. 14B, shown is another pilot design similar to thatof FIG. 14A in that pilot symbols for sets of four antennas are arrangedvertically as indicated at 460. However, the sub-carrier locations usedfor pilot symbols are not uniformly spaced. In other sub-carrierlocations 450, there is a fixed pilot for antennas 1 and 2, and atsub-carriers 470 there is a fixed pilot for antennas 3 and 4. Thus, someof the pilot symbol sub-carriers are used to transmit fixed pilotsymbols while others are used to transmit variable pilot symbols for allfour antennas with one sub-carrier and OFDM symbol per antenna. In theparticular example shown, the spacing between the pilot sub-carriers iseither three or four data sub-carriers. Of course other spacings andarrangements of the fixed and variable pilot symbols sub-carriers can beemployed.

Referring now to FIG. 15, this is a specific example of the pilot designof FIG. 14A. In this example, there is again a repeating pattern of fourOFDM symbols with four such sets of OFDM symbols indicated at420,426,428,430. The first set of four OFDM symbols 420 consists of afirst and second pair 422,424. Data is indicated at 440, pilot symbolsfor antennas 1 and 3 at 442 and pilot symbols for antennas 2 and 4 at444. In terms of sub-carrier assignment, some of the sub-carriers 432are used for pilot symbols and these are each separated by sets of sixdata sub-carriers 434. In this particular example, the pilot symbols areinserted for antennas 1 and 3 during every second pilot sub-carrier 432during the first pair of OFDM symbols 422. Similarly, the pilot symbolsfor antennas 1 and 3 are inserted during every second pilot sub-carrier432 during the second pair of OFDM symbols 424, but in pilot sub-carrierlocations offset from those used in the first pair of OFDM symbols 422.The opposite pattern is used for inserting the pilot symbols forantennas 2 and 4.

Referring now to FIG. 16A, yet another specific example of the pilotdesign of FIG. 14A is shown. In this example, sets of four OFDM symbolsare indicated at 450,452,454. During the first OFDM symbol 450, thereare four OFDM symbols 456,458,460,462. Data is indicated at 470, pilotsymbols for antenna 1 at 472, pilot symbols for antenna 2 at 474, pilotsymbols for antenna 3 at 476 and pilot symbols for antenna 4 at 478. Inthis case, a fixed layout for each pilot of each antenna is shown. Thelayout is similar to that of FIG. 15, but with the layout of each pilotpair being specified exactly. In this case, each pilot pair for a givenpair of antennas is the same each time it is inserted. For example, insub-carrier 469, there is a repeating pattern that consists of a pilotfor antenna 1, a pilot for antenna 2, a pilot for antenna 3 and a pilotfor antenna 4. The same pattern exists in sub-carrier location 466 butoffset from the pattern in 469 by two OFDM symbol locations in time.Pilot sub-carriers 466,469 are separated by data sub-carriers 467.

Referring now to FIG. 16B, shown is another example with verticallyarranged pilots. The arrangement of the pilot symbols for a given OFDMsub-carrier is the same as that of FIG. 16A. However, in this examplethere is also a fixed pilot sub-carrier 445 for the first antenna; afixed sub-carrier for 446 for the second antenna; a fixed sub-carrier447 for the third antenna; and a fixed sub-carrier 448 for the fourthantenna. More generally, in some embodiments, there is a fixedsub-carrier for each of at least one of the four antennas. Sub-carriersduring which only data is transmitted are shown inserted between thefixed pilot sub-carriers and the variable pilot sub-carrier in somecases by three sub-carriers and in some cases by one sub-carrier. Theparticular arrangement of fixed pilot symbols and variable pilot symbolsshown in FIG. 16B is of course to be considered a particular example.Other locations for the fixed pilot symbols and the variable pilotsymbols can alternatively be employed. Furthermore, while a particularlayout for the four pilot symbols of a given pilot block has been shown,the vertical arrangement of FIG. 16B in which there are fixed pilotsymbols and variable pilot symbols can be implemented with alternativearrangements of the pilot symbols for the given antennas.

Examples have been given where the four antennas are separated into twogroups, for example Antennas l&2 as group 1 and Antennas 2&4 as group 2.Any antenna permutation can be selected. They can be fixed for all pairsof symbols, or varying across or even within pairs of symbols.

Examples have been provided in which two sets of the scattered pilotsymbols are introduced for each group, and there is no overlap betweentwo pilot sets in time and frequency.

In some embodiments, the pilot positions are kept identical from even toodd OFDM symbols. Space-time-frequency-coding (STFC) may be applied oneach pilot pair.

In some examples, the scattered pilot pairs may be shifted every twoOFDM symbols (one STBC block) repeating every 6 OFDM symbols (three STBCblocks) for example. More generally, any even number of OFDM symbols canbe used in the repeating pattern.

In some examples, TPS symbols are included and reused to reduce thepilot overhead. Preferably STBC applied on TPS symbols. TPS symbols canbe decoded coherently with the help of the adjacent pilot symbols.Re-encoded TPS symbols can serve as pilot symbols in the detection ofthe data symbols.

Simple and fast channel estimation may be done based on the above pilotsymbols. This involves extracting the received frequency domain datalocated at the pilot and/or TPS sub-carriers corresponding to each pilotset respectively. The next step is calculating the channel responses fortwo transmit antennas in each antenna group based on the received pilotdata and the known sequences transmitted by pilot sub-carriers and there-encoded TPS.

Preferably, all channel responses within one slot are buffered, and thechannel responses of sub-carriers located at the same position as thepilot symbols are obtained by linear interpolation in time direction.

The channel responses of the data sub-carriers at the boundaries(including those at the first and the last sub-carriers in each OFDMsymbol and on the first and last OFDM symbols in each slot) can be setto equal the channel responses of the adjacent pilot symbols.

A 1-D interpolation can then be applied, for example Cubic LaGrangeinterpolator, to reconstruct the entire channel. Other interpolationmethods may alternatively be employed.

If multiple TDD slots are assigned to the downlink to the same receiver,channel estimation performance may be improved by applying the pilotsymbols/re-encoded TPSs in the last two blocks in the previous TDD slotand/or the first two blocks in the next TDD slot to assist the channelresponse interpolation for the current slot.

Advantageously, such an efficient scattered pilot pattern reduces thepilot overhead, especially for transmit systems with four transmitantennas. Slot by slot channel response interpolation supports flexibleTDD UL (uplink)and DL (downlink) partition. Slot by slot channelresponse estimation reduces the buffering requirement and the processingdelay.

The fast signalling channel allows the extraction of TPS every slot ifthis is employed. Fast signalling channel reuse further reduces thepilot overhead.

In some embodiments, some of the transmit antennas can be turned off.For example two scattered pilot groups can be assigned to two transmitantennas to improve the channel estimation performance for a fastfrequency selective fading channel. In further embodiments, the pilotpatterns that have been described are applied to a system that has fewerthan four antennas, for example two or three antennas.

As noted at the outset, the four transmit antennas can come from thesame transmitter, for example a single BTS, or from differenttransmitters, for example different BTSs. They can also come from theantennas of single or multiple mobile stations.

For any of the embodiments described, depending upon the location of thepilots, the pilots can be either space-time coded, space-frequencycoded, space-time-frequency coded or uncoded for the scattered pilots,fixed pilots and the preamble/midamble introduced below. In space-timecoding, there is coding across symbols transmitted by different antennasat different times; in space-frequency coding there is coding acrosssymbols transmitted by different antennas on different frequencies; forspace-time-frequency coding, there is coding across symbols transmittedby different antennas at different times on different frequencies.

According to an aspect of the invention, the scattered pilot power isboosted based on the modulation transmission over the OFDM symbol. Apower assignment for pilot and modulation constellation is listed in thetable below and shown in FIGS. 17A, 17B and 17C. A fixed power boost,for example, 2.5 dB over average power can also be applied.

Physical Modulation Relation w.r.t. Constellations Channel Pilot SymbolQPSK Scattered Same power as scattered pilot Pilot symbol QPSK PreambleSame power as scattered pilot symbol QPSK Traffic 6 dB less power thanscattered pilot symbol 16QAM Traffic Same maximum amplitude as scatteredpilot symbol 64QAM Traffic Same maximum amplitude as scattered pilotsymbol

Referring now to FIG. 18, shown is a time-frequency layout of pilotinsertion for use as either a preamble or midamble. In a preamble, thisdesign would be inserted preceding a set of OFDM symbols. In a midamblesuch a pattern would be inserted somewhere within the set of OFDMsymbols forming. It can be transmitted by antennas in each BTS ortransmitted by multiple antennas from multiple mobile stations. In theexample of FIG. 17, the preamble consists of a pair of consecutive OFDMsymbols 500,502. However, alternatively one such as one OFDM symbol onlycan be employed, or more than two can be employed. The pattern consistsof an alternating pattern of two pilot symbols 509 for antennas 1 and 2and two pilot symbols 506 for antennas 3 and 4. In the event that twoconsecutive OFDM symbols are transmitted as shown in the illustratedexample, preferably the second OFDM symbol 502 is used to transmit anidentical pilot pattern to that of the first OFDM symbol. Preferably,the pairs of pilot symbols, e.g. 506,509 are space-frequency coded.

In another example, shown in FIG. 19, a more detailed layout of thesub-carrier locations is shown in which the repeating pattern is a pilot516 for antenna 1, a pilot 518 for antenna 2, a pilot 520 for antenna 3,and a pilot 529 for antenna 4. In the illustrated example, this patternis repeated in first and second OFDM symbols 512,514 that are identical.Other numbers of OFDM symbols can be used for a midamble and/orpreamble.

Referring now to FIG. 20, shown is a detailed example of a preferredmethod of transmitting a pair of symbols, for example the two symbols ofFIG. 19 or 18, as a preamble, but more generally any two consecutiveidentical symbols. The assumption is that this is transmitted in thecontext of OFDM symbols that have a duration T 610 each preceded by aprefix having a duration Δ 609. In the illustrated example, there isstill a prefix 600 having a duration Δ 609. This is followed by not oneOFDM symbol having a duration T, but rather two OFDM symbols 611,612each having a duration T/2 thus, the total duration of the transmissionof FIG. 20 is the same as the remainder of the symbols in thetransmission, namely T+Δ. The two OFDM symbols 611,612 are identical sothat synchronization can be performed at a receiver. The contents of thefirst OFDM symbol 611 are repeated in the second OFDM symbol 612. Thefirst OFDM symbol 611 is shown to have portions 602,604. Similarly, thesecond OFDM symbol 612 is shown to have portions 606,608 that areidentical to portions 602,604. The prefix 600 is set to equal thecontent in portion 604 of OFDM symbol 611. The nominal effect of this isthat the prefix, portion 604 and portion 608 are identical, and portion602 and 606 are identical. This means that the prefix 600 functions as acyclic prefix for the first OFDM symbol 611, and the second portion 604of the first OFDM symbol 611 functions as a cyclic prefix for the secondOFDM symbol 612. Thus, both of the OFDM symbols 611,612 have therequisite cyclic prefix. This design allows two OFDM symbols with therequisite cyclic prefixes to be sent during the nominal single OFDMsymbol and prefix duration. This allows synchronization to be performedusing a single OFDM symbol duration rather than two symbol OFDM symboldurations. In a preferred example, the regular OFDM symbol is a 2Ksequence, whereas in the two identical OFDM symbols of FIG. 20, each isa 1K sequence.

For the preamble and/or midamble devised with reference to FIGS. 17 and18, in one example modulation scheme, the four antennas are separatedinto two groups. SFBC (space-frequency block coding) is applied to eachgroup, and the two symbols are identical.

The following is a specific example of a preamble/midamble specific PNsequence mapping can be employed for this modulation scheme:

Transmit sequence from antenna 1:

-   -   PN(1), −PN(2)*, PN(5), −PN(6)*, . . . , PN(N−3), −PN(N−2)*    -   PN(2), PN(1)*, PN(6), PN(5)*, . . . , PN(N−2), PN(N−3)*

Transmit sequence from antenna 3:

-   -   PN(3), −PN(4)*, PN(7), −PN(8)*, . . . , PN(N−1), −PN(N)*

Transmit sequence from antenna 4:

-   -   PN(4), PN(3)*, PN(8), PN(7)*, . . . , PN(N), PN(N−1)*        The PN sequence is cell specific code (real or complex) and N is        the number of sub-carriers in preamble/midamble symbol.

In another example modulation scheme each antenna modulates every foursub-carriers.

Channel information obtained from preamble/midamble can be used forcoherent detection of the next OFDM symbol and can also be used foruplink channel sounding when transmitted by mobile stations.

An example of a preamble/midamble specific PN sequence mapping for thismodulation scheme as follows:

Transmit sequence from antenna 1:

-   -   PN(1), PN(5), . . . , PN(N−3)

Transmit sequence from antenna 2:

-   -   PN(2), PN(6), . . . , PN(N−2)

Transmit sequence from antenna 3:

-   -   PN(3), PN(7), . . . , PN(N−1)    -   PN(4), PN(8), . . . , PN(N)

Numerous modifications and variations of the present invention arepossible in light of the above teachings. It is therefore to beunderstood that within the scope of the appended claims, the inventionmay be practiced otherwise than as specifically described herein.

We claim:
 1. A method of transmitting including using four transmit antennas, comprising: for each antenna of the four transmit antennas; generating a respective sequence of OFDM symbols, each OFDM symbol having a plurality of sub-carriers carrying data symbols or pilot symbols, wherein: the pilot symbols are arranged in groups, each group of pilot symbols including a pilot symbol pair for each of the four antennas, and a first group of pilot symbols are inserted into the OFDM symbols such that the pilot symbols for a first two of the antennas are arranged in a first pilot symbol pair, wherein the elements of the first pilot symbol pair are positioned adjacent in time on the same sub-carrier, the pilot symbols for a second two of the antennas are arranged in a second pilot symbol pair, wherein the elements of the second pilot symbol pair are positioned adjacent in time on the same sub-carrier, and the first pilot symbol pair for the first two of the antennas are non-adjacent in frequency to the second pilot symbol pair of the second two of the antennas; and transmitting the sequence of OFDM symbols.
 2. The method of claim 1, wherein, for the first group of pilot symbols, the pilot symbols for the first two of the antennas are separated in time by at least one data symbol from the pilot symbols for the second two of the antennas.
 3. The method of claim 1, wherein, for the first group of pilot symbols, the pilot symbols for the first two of the antennas occupy the same OFDM symbols in time as the pilot symbols for the second two of the antennas.
 4. The method of claim 3, wherein the pilot symbols of the first group for the first two of the antennas are non-adjacent in time a second group of pilot symbols for the first two of the antennas.
 5. The method of claim 4, wherein the pilot symbols of the first group for the first two of the antennas are separated in frequency by predetermined plurality of subcarriers from the pilot symbols for a third group of pilot symbols for the first two of the antennas.
 6. The method of claim 1, wherein, for the first group of pilot symbols, the pilot symbols for the first two of the antennas are separated in time by a first predetermined number of data symbols from the pilot symbols of the second two of the antennas, and, the pilot symbols of the first group of the second two of the antennas are separated in frequency by a second predetermined number of subcarriers from a next group of pilot symbols for the first two of the antennas.
 7. The method of claim 1, wherein the pilot symbols of the first group for the first two of the antennas are adjacent in time from a next group of pilot symbols for the second two of the antennas.
 8. A mobile station, comprising: four transmit antennas; and a transmitter that, for each of the four transmit antennas; generates a respective sequence of OFDM symbols, each OFDM symbol having a plurality of sub-carriers carrying data symbols or pilot symbols, wherein: the pilot symbols are arranged in groups, each group of pilot symbols including a pilot symbol pair for each of the four antennas, and a first group of pilot symbols are inserted into the OFDM symbols such that the pilot symbols for a first two of the antennas are arranged in a first pilot symbol pair, wherein the elements of the first pilot symbol pair are positioned adjacent in time on the same sub-carrier, the pilot symbols for a second two of the antennas are arranged in a second pilot symbol pair, wherein the elements of the second pilot symbol pair are positioned adjacent in time on the same sub-carrier, and the first pilot symbol pair for the first two of the antennas are non-adjacent in frequency to the second pilot symbol pair of the second two of the antennas; and transmits the sequence of OFDM symbols.
 9. The mobile station of claim 8, wherein, for the first group of pilot symbols, the pilot symbols for the first two of the antennas are separated in time by at least one data symbol from the pilot symbols for the second two of the antennas.
 10. The mobile station of claim 8, wherein, for the first group of pilot symbols, the pilot symbols for the first two of the antennas occupy the same OFDM symbols in time as the pilot symbols for the second two of the antennas.
 11. The mobile station of claim 10, wherein the pilot symbols of the first group for the first two of the antennas are non-adjacent in time a second group of pilot symbols for the first two of the antennas.
 12. The mobile station of claim 11, wherein the pilot symbols of the first group for the first two of the antennas are separated in frequency by predetermined plurality of subcarriers from the pilot symbols for a third group of pilot symbols for the first two of the antennas.
 13. The mobile station of claim 8, wherein, for the first group of pilot symbols, the pilot symbols for the first two of the antennas are separated in time by a first predetermined number of data symbols from the pilot symbols of the second two of the antennas, and, the pilot symbols of the first group of the second two of the antennas are separated in frequency by a second predetermined number of subcarriers from a next group of pilot symbols for the first two of the antennas.
 14. The mobile station of claim 8, wherein the pilot symbols of the first group for the first two of the antennas are adjacent in time from a next group of pilot symbols for the second two of the antennas.
 15. An integrated circuit, comprising; for each antenna of four transmit antennas; circuitry to generate a respective sequence of OFDM symbols, each OFDM symbol having a plurality of sub-carriers carrying data symbols or pilot symbols, wherein: the pilot symbols are arranged in groups, each group of pilot symbols including a pilot symbol pair for each of the four antennas, and a first group of pilot symbols are inserted into the OFDM symbols such that the pilot symbols for a first two of the antennas are arranged in a first pilot symbol pair, wherein the elements of the first pilot symbol pair are positioned adjacent in time on the same sub-carrier, the pilot symbols for a second two of the antennas are arranged in a second pilot symbol pair, wherein the elements of the second pilot symbol pair are positioned adjacent in time on the same sub-carrier, and the first pilot symbol pair for the first two of the antennas are non-adjacent in frequency to the second pilot symbol pair of the second two of the antennas; and circuitry to transmit the sequence of OFDM symbols.
 16. The integrated circuit of claim 15, wherein, for the first group of pilot symbols, the pilot symbols for the first two of the antennas are separated in time by at least one data symbol from the pilot symbols for the second two of the antennas.
 17. The integrated circuit of claim 15, wherein, for the first group of pilot symbols, the pilot symbols for the first two of the antennas occupy the same OFDM symbols in time as the pilot symbols for the second two of the antennas.
 18. The integrated circuit of claim 17, wherein the pilot symbols of the first group for the first two of the antennas are non-adjacent in time a second group of pilot symbols for the first two of the antennas.
 19. The integrated circuit of claim 18, wherein the pilot symbols of the first group for the first two of the antennas are separated in frequency by predetermined plurality of subcarriers from the pilot symbols for a third group of pilot symbols for the first two of the antennas.
 20. The integrated circuit of claim 18, wherein, for the first group of pilot symbols, the pilot symbols for the first two of the antennas are separated in time by a first predetermined number of data symbols from the pilot symbols of the second two of the antennas, and, the pilot symbols of the first group of the second two of the antennas are separated in frequency by a second predetermined number of subcarriers from a next group of pilot symbols for the first two of the antennas. 